Calcium channels in photosynthetic eukaryotes: implications for evolution of calcium‐based signalling

Verret, Frédéric; Wheeler, Glen; Taylor, Alison R.; Farnham, Garry; Brownlee, Colin

doi:10.1111/j.1469-8137.2010.03271.x

Cited by 150 publications

(170 citation statements)

References 208 publications

(389 reference statements)

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“…Na V s are thought to have evolved as a result of gene duplication and diversification of an ancestral Ca V , as the four domains of Na V s show higher sequence similarity to the corresponding domains of Ca V s than to each other and have in turn the lowest levels of similarity with K V s (Hille, 1989). Moreover, the fact that Ca V s have a wider phylogenetic distribution than Na V s supports this scenario as well (Verret et al, 2010) (see below). The discovery of bacterial sodium-selective channels (NaChBac) (Ren et al, 2001;Yue et al, 2002;Koishi et al, 2004) has somewhat blurred the evolutionary history of Ca V s and Na V s as NaChBac genes encode a single 6-TM domain that assembles into a tetramer (Durell and Guy, 2001;Ren et al, 2001;Payandeh et al, 2011), and as their selectivity pattern resembles that of animal Na V channels but their filter sequence resembles that of Ca V s, it was suggested that NaChBac channels rather than K V s might be the true ancestors of animal Na V s and Ca V s (Charalambous and Wallace, 2011).…”

supporting

confidence: 51%

“…Hence, it would seem that four-domain Ca V s would be widespread in protozoa. Surprisingly, they are absent in many protist lineages (Verret et al, 2010), although well represented in a few lineages such as ciliates. Most of the increases in cytosolic Ca 2+ influx in protists appear to be through ligand-gated channels, transient receptor potential (TRP) channels or internal stores.…”

Section: Reviewmentioning

confidence: 99%

“…Because of the phylogenetic distance to the metazoans, the loss of Ca V s genes in many lineages (especially in fungi) and the high likelihood of horizontal gene transfers, a well-resolved phylogeny of protist Ca V s, especially their relationship to metazoan Ca V s, has been elusive. Moreover, it is clear that multiple losses of Ca V s have occurred in other lineages such as land plants (Verret et al, 2010). However, the presence of Ca V s in green algae by itself is sufficient to strongly suggest that these channels were already present in the common ancestor of plants and animals (Fujiu et al, 2009;Verret et al, 2010).…”

Section: Reviewmentioning

confidence: 99%

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Evolution of voltage-gated ion channels at the emergence of Metazoa

Moran

Barzilai

Liebeskind

et al. 2015

Journal of Experimental Biology

124

116

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Voltage-gated ion channels are large transmembrane proteins that enable the passage of ions through their pore across the cell membrane. These channels belong to one superfamily and carry pivotal roles such as the propagation of neuronal and muscular action potentials and the promotion of neurotransmitter secretion in synapses. In this review, we describe in detail the current state of knowledge regarding the evolution of these channels with a special emphasis on the metazoan lineage. We highlight the contribution of the genomic revolution to the understanding of ion channel evolution and for revealing that these channels appeared long before the appearance of the first animal. We also explain how the elucidation of channel selectivity properties and function in non-bilaterian animals such as cnidarians (sea anemones, corals, jellyfish and hydroids) can contribute to the study of channel evolution. Finally, we point to open questions and future directions in this field of research. KEY WORDS: Voltage-gated ion channels, Animal evolution, Ion selectivity Introduction: the superfamily of voltage-gated ion channelsThis review aims to cover and clarify the evolution and diversification of metazoan voltage-gated ion channels, particularly at the beginning of multicellularity in the lineage leading to Metazoa and at the emergence of nervous systems. Voltage-gated ion channels are imperative for neuronal signaling, muscle contraction and secretion, and are thought to play a critical role in the evolution of animals (Hille, 2001). Nonetheless, these channels are also found in prokaryotes and viruses, although their roles in these organisms are largely unknown (Martinac et al., 2008;Plugge et al., 2000). The superfamily of voltage-gated ion channels is characterized by the ability to rapidly respond to changes in membrane potential (hence 'voltage-gated'), which results in selective ion conductance. This ion channel superfamily includes voltage-gated potassium channels (K V s), voltage-gated calcium channels (Ca V s) and voltage-gated sodium channels (Na V s). Their α-subunits are composed of four domains (DI-IV), with each domain containing six transmembrane segments (S1-S6; Fig. 1) (Noda et al., 1984;Noda et al., 1986;Guy and Seetharamulu, 1986;Tanabe et al., 1987). Voltage-dependent activation is enabled by conserved positively charged residues at every third position in S4 (voltage sensor) of the four domains, which move outwards upon changes in membrane potential (Noda et al., 1984; Catterall, 1986;Guy and Seetharamulu, 1986), inducing a conformational change that results in opening of the channel pore (Armstrong and Bezanilla, 1974;Stühmer et al., 1989;Papazian et al., 1991;Yang et al., 1996). The pore is formed by the segments S5 and S6, and the selectivity to specific ions is enabled by the selectivity filter, which is composed of conserved residues, specific for the ion conducted by the channel, and these residues are situated at the pore-lining loops (p-loops) connecting S5 to S6 in the four domains ( ...

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supporting

confidence: 51%

Section: Reviewmentioning

confidence: 99%

Section: Reviewmentioning

confidence: 99%

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Evolution of voltage-gated ion channels at the emergence of Metazoa

Moran

Barzilai

Liebeskind

et al. 2015

Journal of Experimental Biology

124

116

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“…Benthic Euglena species, which are common in microphytobenthic biofilms and also show vertical migratory rhythms (Palmer & Round, 1965;Kingston, 1999Kingston, , 2002, probably share the same form of graviperception with planktonic species of the same genus. Furthermore, diatoms possess voltage-and mechanosensitive calcium channels, whose operation is linked to rapid changes in membrane potential (Taylor, 2009), and increases in cytosolic calcium concentration as a response to mechanical stimulus have been reported for Phaeodactylum tricornutum (Falciatore et al, 2000;Verret et al, 2010). Also, the operation of calcium ion channels and changes in cytosolic concentration are known to be involved in benthic diatom motility (Cohn & Disparti, 1994;McLachlan et al, 2009).…”

Section: Discussionmentioning

confidence: 99%

Evidence for gravitactic behaviour in benthic diatoms

Frankenbach

Pais

Martínez

et al. 2014

European Journal of Phycology

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Vertical migration by diatoms is a well-known phenomenon, occurring in intertidal and subtidal benthic biofilms. It is partially endogenously driven, as cell movements can be observed in the absence of external stimuli such as light, temperature or water cover. Although vertical migration of diatoms under constant conditions has often been attributed to geotactic orientation, this hypothesis has never been experimentally demonstrated. Our study tested the gravitactic nature of the vertical migratory behaviour of benthic diatoms in sedimentary biofilms, using an experimental setup designed to distinguish gravitaxis from surface-oriented cell movements. The hourly variation of surface diatom biomass during migratory cycles was compared in homogenized sediment samples kept facing upwards (surface-oriented and gravity stimuli coinciding; controls) and facing sideways or downwards (surface-oriented and gravity stimuli not coinciding). During the experiments, sediment samples were kept in complete darkness in custom-made, sealed measuring chambers designed to avoid any contact with atmospheric air and the formation of physico-chemical gradients near the surface. Microalgal biomass was monitored non-intrusively using PAM fluorometry, by measuring dark-level fluorescence, F o . The results showed a clear effect of sample orientation in relation to the gravitational stimulus. In the controls, a biphasic pattern in surface biomass was observed, with the formation of a clear biomass peak (three-to six-fold increase) followed by a slower decrease. In contrast, in samples facing sideways or downwards, surface biomass also varied but to a much lesser extent (typically < two-fold). These results strongly suggest that, in the absence of light, upward vertical migration of benthic diatoms is mostly guided by negative gravitaxis, supporting the often hypothesized capacity of these cells to sense and use gravity to move vertically within the sediment.

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“…Generally, rapid and local Ca 2+ signals generated in the cytosol depend on a Ca 2+ current driven by a steep concentration gradient between the cytosol (nanomolar range) and its adjacent organelles or extracellular space (millimolar range). This allows the induction of a rapid and strong Ca 2+ rise in the cytosol required for immediate activation of an appropriate response by the simple opening of a few Ca 2+ channels [25] [26]. A calcium signature (characterized by amplitude, duration, frequency and location) can encode a message that contributes to a specific physiological response, after downstream decoding.…”

Section: Introductionmentioning

confidence: 99%

Interactions of Auxinic Compounds on Ca2+ Signaling and Root Growth in <i>Arabidopsis thaliana</i>

Teaster¹,

Sparks²,

Blancaflor³

et al. 2015

AJPS

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Auxinic-like compounds have been widely used as weed control agents. Over the years, the modes of action of auxinic herbicides have been elucidated, but most studies thus far have focused on their effects on later stages of plant growth. Here, we show that some select auxins and auxiniclike herbicides trigger a rapid elevation in root cytosolic calcium levels within seconds of application. Arabidopsis thaliana plants expressing the Yellow-Cameleon (YC) 3.60 calcium reporter were treated with indole-3-acetic acid (IAA), indole-3-butyric acid (IBA), 1-naphthalene acetic acid (NAA), and two synthetic herbicides, 2,4-dichlorophenoxyacetic acid (2,4-D) and mecoprop [2-(4-chloro-2-methylphenoxy) propanoic acid], followed by monitoring cytosolic calcium changes over a 10 minute time course. Seconds after application of compounds to roots, the Ca 2+ signaling-mediated pathway was triggered, initiating the plant response to these compounds as monitored and recorded using Fluorescence Resonance Energy Transfer (FRET)-sensitized emission imaging. Each compound elicited a specific and unique cytosolic calcium signature. Also primary root development and elongation was greatly reduced or altered when exposed at two concentrations (0.10 and 1.0 µM) of each compound. Within 20 to 25 min after triggering of the Ca 2+ signal, root growth inhibition could be detected. We speculate that differences in calcium signature among the tested auxins and auxinic herbicides might correlate with their variation and potency with regard to root growth inhibition.

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Calcium channels in photosynthetic eukaryotes: implications for evolution of calcium‐based signalling

Cited by 150 publications

References 208 publications

Evolution of voltage-gated ion channels at the emergence of Metazoa

Evolution of voltage-gated ion channels at the emergence of Metazoa

Evidence for gravitactic behaviour in benthic diatoms

Interactions of Auxinic Compounds on Ca2+ Signaling and Root Growth in <i>Arabidopsis thaliana</i>

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Calcium channels in photosynthetic eukaryotes: implications for evolution of calcium‐based signalling

Cited by 150 publications

References 208 publications

Evolution of voltage-gated ion channels at the emergence of Metazoa

Evolution of voltage-gated ion channels at the emergence of Metazoa

Evidence for gravitactic behaviour in benthic diatoms

Interactions of Auxinic Compounds on Ca2+ Signaling and Root Growth in &lt;i&gt;Arabidopsis thaliana&lt;/i&gt;

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Interactions of Auxinic Compounds on Ca2+ Signaling and Root Growth in <i>Arabidopsis thaliana</i>